Sensitive relay mechanism



Feb. 1945'. T. R. HARRISON 1 I 2,368,830

SENSITIVE RELAY MECHANISM Filed April 13, 1942 4 SheetsSheet.-1

Feb. 6, 1945.

T. R. HARRISON 2,368,830

SENS ITIVE RELAY MECHANI SM 4 Sheets-Sheet 2 m /ZZZ Filed April 15, 1942 INVENTOR. Thea-mas R. H'arrison...

A f fem er Feb. 6, 1945. T. R. HARRISON 2,368,830

SENSITIVE RELAY MECHANISM Filed April 13, 1942 4 Sheets-Sheet 5 V 32o Mill/111M111" 4. INVENTOR.

L Tl'toma R. Harrison-J Feb. 6, 1945.

T. R. HARRISON 2,368,830 SENSITIVE RELAY MECHANISM Filed April 13, 1942 {Sheets-Sheet 4 H06 PE INDICATOR, naconoen,

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BY AM Patented F eb.- 6, 1945 UNITED STATES PATENT OFFICE SENSITIVE ncur MECHANISM Thomas R. Harrison, Wyncote, Pa., assignor to Minneapolis-Honeywell Regulator Company, Minneapolis, Minn, a corporation of Delaware Application April 13, 1942, Serial No. 438,753

22 Claims.

A galvanometer is connected in' the circuit so as to deflect in one direction or the other from a neutral position in accordance with the variations in the controlling condition. In order to operate relatively heavy control apparatus, for example, a valve, in accordance with the position of the galvanometer pointer, it is customary to provide a mechanism which periodically clamps the pointer, and then drives a secondary element into engagement with the pointer so as to establish a position of the secondary'element which reflects the position of the clamped pointer. The mechanism then applies a brake to the secondary element to retain it in its established posi' tion, and drives the secondary element bodily into engagement with a control member soas to perform a control function in accordance with the position of the secondary element. For example, the secondary element may be made to operate a switch in an electrical circuit for energizing the apparatus under control. When the -secondary element is disengaged from the .pointer, the latter is unclamped so as to be free to move in accordance with variations in the controlling condition. y

An object oi the present invention is to provide an improved and simplified mechanical relay mechanism of the type disclosed in the patent of Willis H Gille, No. 2,331,182, dated October Another object of the invention is to provide an improved and simplified relay mechanism of the type wherein a secondary element is periodically positioned in accordance with the position of a sensitive measuring element, and the secondary element is then utilized to perform a control function in. accordance with its position.

A further object is to construct a sensitive relay mechanism of the type described including an.

improved braking mechanism for retaining the secondary element in the position established by the sensitive measuring element during the performance-of the control function.

A further object of the present invention is to in such a device, means including a single cam and follower for clamping the galvanometer pointer; operating and releasing the brake on the secondary element, and driving the secondary element between the galvanometer pointer and the control element.

Another object of the invention is to provide an improved control element for engagement by the secondary element, wherein the form of the control element is such that the time of engagement of the two elements is modulatingly varied in accordance with the position of the secondary element.

Other objects and advantages of my invention will appear from an inspection of the accompa ying specification, claims, and drawings, in which:

Figure 1 is a somewhatdiagrammatic view or a control system embodying a preferred embodiment of my invention;

Figure 2 is a somewhat diagrammatic view of another control system employing a diflerent embodiment of my invention;

Figure 3 is a somewhat diagrammatic view or 'a control and recording system embodying still another embodiment of my invention;

Figure 4 is a somewhat diagrammatic view of a modified form of control and/or recording apparatus embodying my invention, and v Figure 5 shows a view taken along the line 5-5 of Figure 1, looking in the" direction of the arrows.

Figure 1 shows a system for controlling the supply of heat to a space ID. A radiator ll, located in the space "his supplied with a heating fluid, for example, steam, through a pipe l2. Exhausted fluid is drawn of! Irom the radiator ll through a return pipe Hi. The supply of heating fluid to the radiator I I is controlled by a valve ll in the supply .pipe i 2. V

Any suitable mechanism may be provided for controlling the position of the valve M. For example, the valve I4 is shown as having a stem I 5 attached to a rack I6. The rack I6 is moved by a pinion I! which is driven by a motor 20 through a gear train schematically indicated at 2|. The motor 20 is provided with a pair of field windings 2! and 23,'which when energized cause rotation of the motor in opposite directions. Energizetion of the windings 22 and 23 is controlled by switches 24 and 25, respectively.

Switches 24 and 25 are selectively operated by a-sensitive relay mechanism 26 which is mounted on a supporting plate indicated schematically at 29. The relay mechanism 26 is in turn controlled by a galvanometer 21.

Galvanometer 21 consists of a'polnter 28 carried by a moving coil 30 which is suspended between the poles of a P rmanent magnet M. The

The galvanometcr clamping lever II has pointer 28 normally rests in a neutral position,

The rack It carries a slider 34 which is moved relatively to a slide wire resistance in accordance with the position of the valve ii.

The bridge circuit 31 includes a pair or input terminals 36 and I1, and a pair or output terminals l0 and ll. Output terminal ll i the point at which the slider 34 engages th slide wire 35. A suitable source of electrical energy, shown as a battery 42, is connected between the input terminals II and 31. The coil 3B of the galvanometer I! is connected between the output terminals l0 and ll.

The upper left-hand arm or the bridge .32, as it appears in the drawings, includes a variable resistance l8 and a fixed resistance 44. .The upper right arm of the bridge 32 includes the temperature responsive resistance 33 and a portion of the slide wire resistance 35. The lower left arm of the bridge includes a fixed resistance 45. The lower right arm oi the bridge includes a fixed resistance 40 and the remaining portion of the slide wire resistance II.

The resistance 43 may be manually adjustable, and its Purpose is to establish the temperature in th space II at which the bridge circuit will be balanced when the valve I4 is in a given position. In other words, the function of the variable'resitestancefl is to set the control point of the sys- The sensitive relay mechanism 26 comprises means including a lever ll tor-"clamping the galvanometer pointer 28, a secondary pointer II which is periodically positioned in accordance with the position of the clamped pointer and is then moved to selectively actuate the switches 24 and 25 in accordance with its position, mechanism including a supporting arm 52 for carrying the secondary pointer II and for moving it alter nately into cut with the clamped pointer II and with the switches 24 and "(and a braking arrangement for maintaining the position of the secondary pointer II with respect to its supports armll.

w an elongated opening II in one of its ends, through which opening the pointer it passes. Immediate ly in back of the opening 53, the pointer 28 passes under a stationary bar 54; The opposite end of the clamping lever I. carries a follower II which cooperates with a cam ll. The lever II is supported at an intermediate point by. means of a crossed spring pivot arrangement 51.

The cross spring pivot l'i n o! a conventional and comprises a bracket ll attached to the mounting plate by means or a pin and slot connection I. The bracket plate 58 has a pair of upstanding lugs I, to which are attached, as by welding or; riveting, a pair of normally flat springs 82. Theropposite ends of the spring members u are attached to similar upstanding lugs ll on the clamping lever II. The central portions of the springs '82 are spaced from each other so that there is no friction between them.

The supporting arm I! and a brake arm 84,

hereinafter referred to as the primary brake arm, are Journalled on a stub shaft 85 attached to the mounting plate 29. The arm 52 pivotally supports, as at 66, the secondary pointer iii. The pointer 5| comprises an elongated vertical portion and a lateral extension ll appearing to the left oi the pivot 56.

The extension 61 carries a brake shoe it in the iorm of a circular pin, which is attached to its rear surface. The pin 18 is adapted to be clamped betweencan a'rcuate surface H on the primary brake arm 81 and an arcuate surface 12 on a secondory brake arm 13. The center of curvature of these arcuate surfaces is the center of rotation of secondary pointer 8| which carries brake shoe pin 10. The primary brake arm ll carries at an intermediate point a follower H which cooperates with a cam 15. A tension spring 16 biases sup porting arm 52 and primary brake arm i10l' movement towards each other. The secondary brake arm 13 is pivotally attached to the primary brake arm 84, as at TI. A tension spring 80, one end of which is fixed, has its other and connected to the secondary brake arm 13 so as to tend to rotate the secondary brake arm in a counterclockwise direction about its pivot 11. The secondary. brake arm 13 carries on its upper end an extension 8| which cooperates with an adjustable arm 64 and the supporting arm 82.

A plate 83 is adjustably supported on the plate 28 by means .of a pin and slot connection It. This plate Bl carries a stop pin II, which projects forwardly into the path or movement of the lower end of the elongated vertical portion of the secondary pointer I i Switch 24 comprises a stationary contact I! which is adjustably mounted with respect to the mounting plate 28 by means or a screw and slot connection 88. and a movable contact OI mounted on a longflexible switch linger II. The switch finger 8! has amangular extension II which lies in the path of secondary pointer II as it is moved to the right by the operation or the driving mechanism. Switch II similarly comprises a stationary contact I! mounted adiustably with respect to plate 2! and a movable contact I mounted on a long flexible linger ll.

Figure 5 shows in detail the supporting structure of stationary'contact it of switch". It will be seen that contact Q! is mounted on an upstanding leg in of a bracket plate III, 0! flexible material. A heavier bracket plate 83 overs lies the plate I33, which is spaced from the mounting plate 2! by a suitable insulation piece I. Screws I8 pass'through holes in the plates 03 and Ill, and thread'edly engage insulation piece it and plate 2!. Insulating washers I separate the heads of screws 88 from plate I.

The holes in the plate 93 not only electrically'sepstate the screws 88 from the plates 93 and I, but also permit a rough adjustment of contact 92 relative to plate OI. Fine adjustment of contact 82 is controlled by a boltlfl. which is threaded through an upstanding lug III on the plate 93. The leg III of plate Ill is self-biased to engage the end of bolt I. The position of aacaeso I 3 contact 82 relative to plate 95 may therefore be nnely adjusted by turning bolt I85.

A condenser I30 is connected across the contacts of switch 24, and a condenser I3I is connected across the contacts of switch 25, for spark prevention purposes.

The cams 56 and I5 are mounted on a common shaft 96 which is continuously rotated by a constant speed motor 91 through a gear train schematically indicated at 98. The motor 91 is provided with a winding I connected to power supply lines IOI and I02.

Energy for the operation of motor 20 is supplied through a transformer I03 having a primary winding I04 and a secondary winding I05.

The primary winding I04 is connected to suitable power supply lines which may be connected with lines IN and I02, although such connection is not shown in the drawings.

Operation of Figure 1 When the parts are in the positions shown in the drawings, the temperature of the space I0 is at the value at which it is desired to maintain.

Bridge circuit 32 is balanced, and the galvanomreached a position such that the galvanometen pointer 28 has been clamped and the secondary pointer 5| has been moved into engagement with the clamped pointer 28. The angularposition of the secondary pointer 5I with respect to its supporting arm 52, is at this time determined by the positions of the clamped pointer 28,-and the stop pin 85, which engage the upper and lower extremities respectively of the elongated vertical portion of the pointer 5 I Engagement of pointer 5| with pointer 28 and stop 85 has prevented further movement of pivot 66 to the left. Therefore supporting arm 52 remains stationary. Primary brake arm 64 has moved on to the left under the influence of sprin 80 acting through the pivot II to maintain follower I4 in engagement with cam I5. The extension 8| of secondary brake arm 53 has engaged stop 82, so that brake shoe I0isfree from secondary brake surface The continued movement of primary brake arm 64 to the left has also freed brake shoe I0 from surface II Therefore, secondary pointer 5I has been freed to assume a position with respect to supporting arm 52 which is determined only by the relative positions of stop 85 and the clamped pointer 28.

As the motor 91 continues to rotate, the cam 56 is driven in a counter-clockwise direction from the position shown in the drawings, and the folpointer 28 -to clamp it against the bar 54, the follower 55 is held free of the low dwell portion II 0. When thefollower 55 moves up the riser I06, the lever 50 is'rotated clockwise about its pivot,

- switch 24, but switch 25 would not be operated.

thereby movingthe aperture 55 downwardly and freeing the pointer 20. As the follower 55 reaches the upper end of riser I06, the upper end of the aperture 53 moves down below the lower edge of the bar 54, thereby giving pointer 28 a slight downward kick, which serves to free it in case it adheres to the bar 54.

when the follower 55 moves down the drop-on portion I01, the upperledge of aperture 53 moves back in front of the bar 54 so as to avoid frictional engagement between the' pointer 28 and wardly and engages the pointer 28, clamping itagainst the bottom of the bar 54. The pointer 28 remains clamped while the low dwell portion IIO passes the follower 55.

As "cam I5 rotates in a counter-clockwise direction from the position shown in the drawings, follower 14 moves successively up a riser portion II5, down a long slow drop-01f portion H6, and then down a rapid drop-off portion I II to a short low dwell portion II8.

The follower I4 is shown in the drawings as engaging the low dwell portion II8. When follower I4 moves up the riser portion II5, the primary brake arm 64 is rotated clockwise about its pivot. This brings braking surface II into engagement with brake shoe I0, and after this engagement the secondary pointer .5I and supportingarm 52 are moved to the right by the force supplied from the primary brake arm 64 throughthe brake shoe 70. As the motion of primary brake arm 64, pointer 5|, and supporting arm 52 continues to the right, the brake shoe I0 engages the brake surface I2 on the secondary brake arm I9. This engagement picks up the extension 8| from the stop 82 and thereafter the whole assembly consisting of supporting arm 52, secondary pointer 5I, and brake members 64 and I3 moves about the pivot 65 as a unit. When the follower I4 reaches the upper extremity of riser II5, the secondary pointer 5I is at its extreme limit of movement to the right. I

When the secondary pointer 5i reaches its -extreme right-hand position, it engages and operates either switch 24 or switch 25, or neither, depending upon the angular position of pointer 5I with respect to its supporting arm 52. When the angular position of pointer M with respect to supporting arm 52 is that shown on the drawings, it will engage neither switch 24 nor 25. If the secondary pointer 5I were displaced in a counter-clockwise direction about the pivot 65 from the position shown in the drawings, the lower end of the pointer 5| would engage extension SI of switch finger 89, thereby opening On the other hand, if the secondary pointer 5i were displaced in a clockwise direction from the position shown; the upper end of the pointer 5| would engage and operate switch 25, but switch 24 would not be operated.

It should therefore be seen that the. sensitive relay mechanism selectively operates switches 24 and 25, depending upon the direction in which 4 the pointer 28 is displaced from its neutral position. The riserportion N5 of cam 55 is rather abrupt, so as the follower I4 moves alon it, the pointer BI is moved rapidly into engcgement with the switches 24 or 25. Therefore the moment of engagernent of pointer 5| with either switch 24 or 25 is determined largely by the riser portion H5, and not by the angular position of pointer 5| with respect to the supporting arm 52. The slope of the drop-off portion H6 is rather gentle, however, so that the pointer 5! is moved slowly away from contacts 24 and 25. Therefore the switch 24 or 25 will be actuated for a period of time, represented by an arc onthe surface of cam 15, which is dependent upon the angular position of secondary pointer H with respect to supporting arm 62. While the length of this period of time is also determined by the speed of the motor 21 'and the shapes and sizes of the various cooperating elements of the mechanism, these factors are constant and hence do not cause any change in the length of this period. Since the motor l1 operates at a constant speed, it should further be apparent that the length of time during which the switches 24 or 2.5 are operated by the pointer BI is determined by the magnitude of the deflection of pointer 28 from its neutral position, which of course determines the angular deflection of the secondary pointer II from its normal neutral position. When the follower I4 reaches the end of the slow drop-of! portion Ill and moves down the rapid drop-oil portion Ill, the secondary pointer and its related parts are moved rapidly to the left so as to again release the braking mechanism and position the secondary pointer 5| in accordance with the position attainedby the pointer 2l during the interval when it was free to move. As this movement takes place, the extension ll is again picked up by the stop 82, thereby releasing brake shoe Hi from the braking surface 12. When primary brake arm II moves on, freeing shoe II from braking surface H, the secondary pointer ii is again free to be positioned by the stop ll and the pointer 28. The whole cycle of relay operation is then repeated Switch 24 controls an energizing circuit for motor winding 22. which may be traced from the upper terminal of transformer secondary winding Ill through conductors in and I, bracket plate ll, stationary contact ll, movable contact ll, flexible switch finger ll, a bracket I22, "a conductor I22, winding 22, and a conductor to the lower terminal of secondary winding Switch 2l controls an energizing circuit for winding 22 of motor 2l, which may be traced from the upper terminal of secondary winding Ill, through conductor l2l, a conductor I25, bracket late ll, stationary contact 92, movablecontact l4, flexible switch finger ll, a bracket I", a conductor I21, .winding H, and conductor I24 to the lower terminal of secondary winding Ill." It should be noted that bothswitches 24 and 2| are normally closed, so that opposing windings asaaeso rm due to the inertia of the rapidly moving motor.

Let it now be assumed that the temperature in the space Iii increases above the value which it is desired to maintain. This causes an unloalance of the bridge circuit 32 in such a direction as to cause a flow of current from output terminal i i to output terminal lll. This flow of cur rent causes a deflection of galvanometer pointer 28 to the left of the position shown in the draw logs. When the pointer 51 is next positioned in the course of the operation of the sensitive relay mechanism 28, it is set at a position displaced in a counterclockwise direction with respect to supporting arm 52 from the position shownrin the drawings. When the secondary pointer H is moved to the right, its lower end engages the switch 24. thereby deenergizing motor winding 22. Motor winding 22 then causes rotation of motor 2l in a direction such as to close thevalve l4 slightly. thereby moving slider 34 downwardly along the slide-wire l5 and decreasing the resistance in the upper right-hand arm of the bridge circuit, so as to restore the bridge to a condition of balance. When the pointer 2l is next clamped by the relay mechanism 2l, it will again be in its balanced position, and the switches 24 and 25 will not be actuated If the departure of the temperature in the space ll from the desired value .persists, however. the switch mechanism will continue to be periodically actuated until such time as the position of valve H has been corrected sufliciently to overcome the change in temperature of the space In.

Similarly, a drop in temperature in the space III will cause deflection of galvanometer pointer 2l to the right, with the resultant opening of switch 25 and operation of the valve l4 towards open position so as to increase the supply of heat to the space ll, thereby overcoming the drop in temperature.

Figure 2 Figure 2 shows a somewhat different type of control system in which the sensitive element is a thermocouple rather than a temperature responsive resistance member. In Figure 2 also, a modified type of relay is employed in which the" galvanometer clmnping mechanism is operated by the secondary brake member, so that only a single driving cam need be employed.

Figure 2 shows a furnace 2 having a burner 2ll, to which fuel is supplied through a pipe 2l2, the supply of fuel being controlled by a valve 2ll.l The valve 2ll is provided with a stem 2, on which is mounted a rack 2". The rack 2" is operated by a pinion 2ll driven by a motor lll schematically indicated at 2". Motor 2l| is provided with a pair of field windings 2H and U2 which control its rotation in opposite directions. Encrgization of windings 2H and 2 is 22 and 23 of motor 2l are normally energized.

When one of the switches 24 and 28 is opened.

one of the windings n and a is deenergised ms the other causes rotation of the motor. When, in

the course of operation of the relay mechanism,- the switch which was opened again closes, both circuits are complete, and a sort of dynamic braking action is obtained which-stops the motor quickly, thus overcoming any tendency to overtpotentiometer resistance 22l 'by a conductor 224.

The conductor 2|! is connected to a'slidr 22I ascasso mounted on the stem 264 of valve 263 and movable along the potentiometer resistance 22! in accordance with the position of the valve- The galvanometer 222 includes a permanent magnet 226, between the poles of which the coil .223 is suspended. Coil 223 carries a pointer 221,

The sensitive relay mechanism 236 includes a secondary pointer 23!, means for; reciprocating the pointer 23! first into engagement with the pointer 221 and then into engagement withv the switches 2!3 and 2!4,' clamping mechanism for clamping the pointer 221 while it is engaged by the pointer 23!, and braking mechanism for preventing movement of the pointer 23! with respectto it supporting arm during the time it engages the switches 2!3 and M4.

' The entire sensitive relay mechanism 236, with the exception of the galvanometer 222, is supported on a plate schematically indicated at 232.

The galvanometer clamping mechanism includes a stationary bar 233 and a lever 234 pivoted as at 235 on' the plate 232. A spring 236 biases the lever 234 for counterclockwise rotation about the pivot 235. Such counterformer 266 having a primary winding 261 and a secondarywinding 268.

- Operation of Figure 2 When the parts are in the position shown in the drawings, the valve 263 is approximately half-way open, and the temperature. within the furnace 266 is at the value which the system has been set to maintain. There is no potential across the terminals of the galvanometer 222, and hence the pointer 221 is in its center position.

The cam 246' is provided with a long slow rise portion 216, and an abrupt drop-off portion 21!. The cam 246 is rotated clockwise as indicated by the arrow in the drawings.

moved a substantial distance up the rise portion 216, thereby moving the secondary pointer 23! towards the pointer 221. The extension 256 on secondary brake arm 243 has just engaged the stop bolt 246 on the clamping lever 234. As

rotation of cam 246 continues, secondary brake clockwise rotation of lever 234 is limited by a stop 231 mounted on the plate 232. When the lever 234 is against the stop 231, it is free of the pointer 221, so that the latter can moveunder the influence of the galvanometer 222. The lever 234 also carries a downward extension 238, and is provided at its lower end with an adjustable bolt 246, which acts as a stop for a secondary brake arm 243.

Pivotally mounted on the plate 232 a at 24! are three arms: a forked arm 242, the secondary brake arm 243, and a supporting arm 244. One of the forks of the arm 242- carries a follower 245 which cooperates with a continuously rotating cam 246. A' spring 241 attached to the arm 242 biases it for rotation about the pivot 24! in a clockwise direction, thereby tending to maintain the follower 245 in engagement with cam 246. The other fork of am 242 carries a braking surface 256, and corresponds generally provided with an extension 256 for engagement with the stop member 246 which is mounted on extension 238 of lever 234.

The secondary pointer 23! comprises an elongated vertical portion and a lateral extension 251 which carries at its extremity a brake shoe 266 which is adapted to engage the braking surfaces 256 and 26!.

Cam 246 is driven by a constant speed motor 26!, having a winding 263 connected supply line 264 and 266.

The motor 261 is supplied with power from the supply lines 2 and 266 through a transto suitable member 243 is held by its engagement with the bolt 246, so that surface 25! separates from brake shoe 266. This extends spring 252 and compresses spring 236, rotating clamping lever 234 clockwise about its pivot 235 and clamping pointer 221 between the lever 234 and the bar 233. As themotion of the cam 246 continues, brake shoe 266 remains in engagement with braking surface 256 until the pointer 23! engages either the clamped pointer 221 or stop pm 254. Engagement of secondary pointer 23! with either of these latter members causes a tensioning of the spring 253 sufficient to release the pressure between brake shoe 266 and surface 256, thereby permitting secondary pointer 23! to rotate about its pivot. The secondary pointer 23! accordingly rotates about its pivot until it engages both stop pin 254 and the clamping. pointer 221. The angular position of secondary pointer 23! with respect to its supportingarm 244 is then determined by the relative positions of these two members.

When the follower 245 approaches the end of riser portion 216, all the above described operations have been completed, and the secondary pointer 23! has been positioned in accordance with the position of clamped pointer 221.

When the follower 245 rides down the abrupt drop-o1! portion 21!, the arms 242, 243, and 244 will be rotatedrapidly clockwise by the spring 241. During this phase of the operation, the arm 242 will first move alone until the braking surface 256 engages the brake shoe 266. After this engagement, arms 242 and 244, together with secondary pointer 23 move as a unit. This moselectively in accordance with the position of the galvanometer pointer 221. The operation is exactly analogous to that described in connection with Figure 1.

The ener izing circuit for winding 2!! may be traced from the upper terminal of transformer secondary winding 268 through a conductor 213,

When the parts are in the positions shown, the follower 245 has switch 213, conductors 21! and 212, winding ii I, and a conductor 213 to the lower terminal oi! secondary winding 263.

The energizing circuit for winding 7H2 may be traced from the upper terminal oi winding 268 through conductor 210, switch 2, conductors 214 and 215, winding 2l2, and conductor 213 to the lower terminal of transformer winding 268. A condenser 216 is connected between con ductors 21! and 214 to reduce sparking at the contacts of switches 2|3 and 2l4.

Figure 3 Figure 3 shows a system in which a somewhat different type of potentiometric network is em ployed. This may be, for example, the Brownpotentiometric network disclosed in the paterit to Thomas R. Harrison, No. 1,898,124, dated February 21, 1933. In this figure also, a difierent type of sensitive relay mechanism is employed, in which the modulation of the contact timing in accordance with the angular position of the secondary pointer is obtained from the shape of the contacts themselves rather than from the speed of operation ofthe secondary pointer.

Figure 3 shows a furnace 300 having a burner 30!. The supply of fuel to the burner 30! is controlled by a valve 302. A motor 355 operates the valve 302 through a gear train schematically indicated at 322 which is connected to a pinion 303 operating a rack 304 mounted onthe stem' 305 of the valve 302. Motor 396 is provided with a pair of field windings 3H) and 319, which con" trol its operation in opposite directions. Energization of windings 3! 3 and 3|9 is controlled by a balanced relay 329, which responds to the occurrence of an unbalance in a normally balanced network 343, which includes a control potentiometer 349 and a rebalancing potentiometer 354. Slider 359 of rebalancing potentiometer 354 is driven by motor 336 through gear train 322. Slider 31! of control potentiometer 343 is driven by another motor 306 through a gear train 301.

In the network 343, the slidewires 315 and 316 of the potentiometers 349 and 354, respectively have their 1eit-hand terminals connected by a conductor 311 and their right-hand terminals connected by a conductor 318. The conductors 311 and 313 include opposing windings 336 and 331 of the balanced relay 329. The relay 329, which may preferably be of the type described in Patent No. 2,169,141, issued to Willis H. Gille on August 8; 1939, operates a switch arm 313 between a pair'oi' contacts 333 and 309. Energy is supplied to the network 343 through a conductor 330 attached to slider 31!, and a conductor 39! attached to slider 353. The conductors 330 and 39! are connected to a secondary winding 310 of a transformer 363.

Motor 306 also drives, in addition to control potentiometer 349. a recorder pen 303 across a chart 309, the chart being driven by a constant speed motor 3! The connection from the motor 300 to the pen-303 is through another gear train schematically indicated as 3!2 to a screwshaft 3i3 on which moves a carriage 3l0 supporting the pen 300. Motor 306 is provided with a pair of field windings 3 and 3l5 which control its operation in opposite directions.

A thermocouple 320 is mounted in the furnace 300 and is connected by a pair of conductors 3!! and IN to the terminals of a potentiometric network 32!.. The network 32! consists of a ascents bridge circuit 323 which operates as a source or potential and includes a slide-wire resistance 324. A dual slider 325 is mounted on the pen carriage 3H) and carries one contact which engages the slide-wire 323 and another contact which engages a rheostat 326 connected in series with the thermocouple 320 and a galvanometer coil 321 on the galvanometer 323. The purpose oi the rheostat 326 is to keep the resistance of the network 32!, as measured from the thermocouple terminals, substantially constant for all positions of slider 325 with respect to potentiometer resistance 323.

The galvanometer 323 includes the usual permanent magnet 336 and a pointer 33! carried by the moving coil 321.

The energizaticn of motor windings 3H and 315 is controlled by switches 332 and 333, respectively. The switches 332 and 333 are operated selectively by a sensitive relay mechanism 334 in accordance With the position of the galvanometer pointer 33 l.

The relay mechanism 334 includes a. galvanometer clamping lever 335 which is operated by a continuously rotating cam 336. Since the construction and operation of cam 336' and lever 335 is entirely analogous to that of a cam 53 and lever 50 of. Fig. 1, further explanation of this structure is believed to be unnecessary.

The sensitive relay mechanism 334 also ineludes an arrangement for reciprocating a secondary pointer 331 between a first position where it engages the galvanometer pointer 33! and a second position where it engages members 333 and 339 which actuate the switches 332 and 333, respectively.

The mechanism which reclprocates the second ary pointer 331 comprises four arms 340. 34!, 342, and 343, all pivoted at 344 to the supporting plate 323.

The arm 340 is a driving and primary brake arm. It takes the form of a bell-crank lever having one extension 345 carrying a follower 343 which is driven by a cam 341, and another extension 35!! which serves as a primary brake arm. A spring 35! biases arm 345 or lever 340 upwardly so as to maintain the follower 346 in engagement with cam 341. The primary brake arm 350 has a brake surface 352.

The arm 33! serves'as an intermediate pointer between the galvanometer pointer 33! and the secondary pointer 331. Its purpose is to take part of the strain or! the galvanometer pointer 33! when the secondary pointer 331 is being positioned. A tension spring 353 biases the intermediate pointer 34! for movement to the left and into engagement with galvanometer pointer 33!. Such engagement is prevented, however, by a stop pin 343 carried by supporting'arm 342. The pointer 34! carries a stop pin 354 which is adapted to engage the upper end of the see- I ondary pointer 331.

The arm 342 is a supporting arm for the secondary pointer 331. A spring 355 shown as attached to pin 343 biases the supporting arm 342 for counter-clockwise rotation about the pivot galvanometer pointer 33 l.

A plate 333 is pivotaliy mounted on the plate 323 as at 33L The plate 330 carries a stop pin 332. The plate 333 may be adjusted in any predetermined angular position with respect to the plate 329 by means of a pin and slot connection 333.

Cams m and :41 are mounted on a common shaft which is driven by a constant speed motor 334. The motor 334 is provided with a winding 335 connected to suitable power supply lines 363 and 351.

Power is supplied to motor 333 from lines 336 and 331 through a transformer 333 having a primary winding 333 and a secondary winding 313.

Operation of Figure 3 The operation of the relay mechanism 334 will first be briefly described. When the parts are in the position shown in the drawings, the secondary pointer 331 is at its right-hand limit of movement. It is maintained in this same position for a time dependent on the length of a low dwell portion 312 of cam 341.

As cam 341 rotates counter-clockwise, as indicated by the legend in the drawings, the follower 343 moves up a riser portion 313 and down a dropoff portion 314, returning to the low dwell portion 312.

when the follower 343 moves up the riser portion 313, the arm 343 is rotated counter-clockwise about the pivot 344. The secondary-brake arm 343 follows this movement until its upper end engages the stop 351. The supporting am 342 also follows this movement under the influence of the biasing spring 353. This movement of arm 342, carrying stop pin 343 to the left, permits intermediate pointer 34! to move to the left until it engages galvanometer pointer 33L It thereupon stops, setting a position of pin 354 dependent on the position of pointer 33L When the secondary pointer 331 engages either stop 332 or stop 354, the pressure between the braking surface 352 and braking pin 343 on pointer 331 is released. This permits secondary pointer 331 to rotate about its pivot on supporting arm 342 until it engages both stops 354 and 332. The angularposition of secondary pointer 331 with respect to its supporting arm 342 is thereby determined in accordance with the position of the clamped galvanometer pointer 33!.

When the follower 343 moves down' the dropof! portion 314 of cam 341, the brake arm 353 moves back to the right. When braking surface 332 engages brake shoe 343 on secondary pointer 331, it forces pointer 331 and supporting arm 342 to follow its motion to the right. As this motion continues, the intermediate pointer 34! is carried to the right out of engagement with pointer 33l by the action of the stop pin 343. Also, the cam 333 operates on the lever 335 to free the As the motion of secondary pointer 331 to the right continues, pin 343 engages-braking surface 353 on the secondary brake member 343. The pin 343 is then securely clamped between the two brake members. 7

As pointer 331 approaches the right-hand end of the path of movement, it engages one of the switch operating members 333 and 333, depending upon its angular position with respect to the supporting am 342.

Switch 332 controls an energizing circuit for winding 3" of motor 333. This circuit may be traced from the upper terminal of transformer paths have a common secondary winding 313 through a conductor 333, switch actuator 333, switch 332, a conductor 33!, motor winding 3, and a conductor 332 to the lower terminal of secondary winding 313.

Switch 333 controls an energizing circuit for .winding MB of motor 335. This circuit may be traced from the upper terminal of transformer secondary winding 313 through conductor 333, switch actuator 339, switch 333, a conductor 333, motor winding 3l5, and conductor 332 to the lower terminal of transformer winding 313.

A condenser 334 is connected across the contacts of switch 332, and a condenser 335 is connected across the contacts or switch 333, for spark prevention purposes.

The switch actuating. members 333 and 333 are provided with curved portions which are engaged by the secondary pointer 331. These curved portions extend obliquely toward the secondary pointer 331, so that as the angular deflection of pointer 331 from its normal position increases, the period of its engagement of the switch actuator 333 or 333 also increases. It will therefore be understood that the switches 332 and 333 are intermittently operated for periods of time which are modulatingly varied in accordance with the deflection of the galvanometer 33i from its center position.

It may be stated that the right-hand end of secondary pointer 331, which engages the switch actuators 333 and 333, is reciprocated along one of a plurality of concentric arcuate paths. These center at the pivot 344.

' A change in the angular position of secondary pointer 331 with respect to its supporting arm 342 causes the right-hand end of the secondary pointer to shift from one of these paths to another of difierent radius. The switch actuators 333 and 339 extend obliquely to these paths, so that the period of engagement of pointer 331 with either of the actuators 333 or 333 depends upon the particular path in which pointer 331 is moved. Likewise, the particular actuator engaged by the pointer 331 is determined by the selection of a particular path. The selection of one of these concentric paths is made in accordance with the magnitude of a controlling condition, as reflected in the position of galvanometer pointer 33l, by the sensitive relay mechanism described.

Energization of either winding 3 or N5 of I motor 335 causes rotation of that motor so as to drive the screw shaft 313 in the proper direction to move slider 325 so as to rebalance the network 323. At the same time, the pen 333 moves across the chart 333 and records thereon the change in temperature which causes operation of motor 305 to be initiated.

At the same time, operation of motor 336 causes slider 31! to be driven across slidewire 315 so as to unbalance the network 343. Wheri the sliders 31! and 353 are in their. center position,as shown in the drawings, the network 343 is balanced, since the'current flowing through coil 333 of relay 323 is the same as the current flowing through coil 331. At such a time, therefore, the switch arm 313 remains between the contacts 333 and 333, not engaging either one;

When the slider 31l moves to the left from the center position shown in the drawings, the cur- This unbalance in. the coordination oi" coils and 391 causes switch. arm. 919 to be moved perature adjacent the sensitive element 29 to its desired value, At the same time, slider 359 of rebalancing potentiometer 354 is moved to theright along slidewire 319, This motion of valve 392 and 01' slider 359 continues until the slider 359 has reached a position where the balanced condition of the network 349 is restored. When such a balanced condition is reached, the switch arm 319 again assumes a position midway between contacts 389 and 399, thereby deenergizing winding 319 of motor 398.

It will be readily understood that when net work 348 is unbalanced in the opposite sense, switch arm 319 is moved into engagement with contact 399, thereby completing an energizing circuit for winding 319 or motor 399. This energizlng circuit may be traced from the lower terminal of transformer secondary winding 319 through conductors 399 and 392, switch arm 319, contact 349, a conductor 339, winding 319, and conductors 394 and 391 to the upper terminal of transformer secondary winding 319.

The system shown in Figure 3 therefore operates upon a change in temperature adjacent the thermocouple 329, to make a record of that change upon the chart 393, and simultaneously to correct the position or the valve 392 so as to restore the temperature to its desired value.

Figure 4 I have illustrated in Figur 4, a modification of my inventionwherein a rebalancing potentiometer in a control network is actuated mechanically by my sensitive relay mechanism, rather than by a reversible electrical motor controlled by the relay mechanism.

In Figure 4 a sensitive relay mechanism, gen erally indicated at 491 is operated in accordance with the'position 01' a pointer 492 of agalvanometer 493. able coil 494 carrying the pointer 492. Coil 494 is connected in a potentiometrio network 495 including a thermocouple 494 and a rebalancing sl de-wire 491.

The slide-wire 491 is circular in form, and is rotatable about a shaft 499. A stationary slider 4 I 9 cooperates with the slide-wire 4 91,

The network 495 nected to the terminals oi slide-wire 491 through conductors 412 and 413. A rheostat 414 i included in the connections between battery 411 and slide-wire 491 in order to adjust the control The galvanometer 493 include a movincludes a battery 411 -cona point of the system. Slider 419 is connected toone terminal of galvanometer coil 494 through a conductor 419. The other terminal of coil 494 is connected to onctermlnal of thermocouple 499 by a conductor 419. A conductor 411 connects the noslte terminal of thermocouple 499 with condu. 412.

sensitive relay mechanism 491 includes a clamping lever 429, which is per odically operated to clamp the galvanometer pointer 492, a

encase secondary printer 452i which ciprocated between a position whet ntiages Lb pointer 492 and another position where it iristionallv engages slidc-wiro 491, and a driving arm 422, which drives secondary pointer 421 while it is in engagement with slide-wire when as to pivotally mounted,

counterwlocl'iwise against a stop 429. A down wardly extending arm 421 of lever 429 carries at its lower extremity a bolt 423. The bolt 429 may be threadedly adjustable with respect to the am .421. A fixed bar 439 is mounted on the opposite side of pointer 492 from clamping lever 429, so that the pointer 492 may be clamped between ,the lever 429 and bar 439.

The secondary pointer 421 is carried by'a slip friction pivot arrangement 431 at the extremity of a supporting arm 432. The supporting arm 432, the driving arm 422, and a bellqcrar k lever 433 are all pivotally mounted on a fixed support, as at 434. Supporting arm 432 and the hellcranlt lever 433 are provided with suitable mating surfaces, as at 435 and 439, respectively. A tension spring 431 has its extremities fastened to the arm 432 and lever 493 in such a manner as to maintain the surfaces 435 and 435 in engagement. The spring 431 serves as a strain release to permit separation of surfaces 435 and 436 during operation of the relay mechanism.

- The secondary pointer 421 is substantially T shaped and comprises an upwardly extending arm 449, a downwardly extending arm 441, and 'a latorally extending arm 442. The upwardly extending arm 449 is adapted to engage the galvanometer pointer 492. The downwardly extending arm 441 is adapted to engage a stationary stop 443, which may he supported on a bracket (not shown) extending in front of the driving "arm 422 so as not to interfere with the move ment thereof. The laterally extending arm 442 carries on the underside of its extremity o. pin 444 adapted to engage the surface of slide-wire 491.

The driving arm 422 carries at its upper end an extension 449 adapted to engage the belt 423 mounted on lever 429, and thereby operate the clamping lever 429. The lever 422 also carries a pair of pins 448 and 441 which drivingly engage the secondary pointer 421. The arm 422 carries a follower 448 adapted to engage a continuously rotating cam 499. A tension spring 451 biases arm 422 so as to maintain the follower 448 in engagement with 09.111 459. A tension spring 452 connects driving arm 422 and the lowor end of bell-crank. lever 433. The spring 452 tends to rotate the bell-crank lever clockwise so as to cause engagement between pln 444 and slide-wire 491. The cam 459 carries a pin 493 which is adapted to engage the lower end of bellcrank lever 433 and rotate it countermlockwisc against the bias of spring 452.

Operation of Figure 4 The lever 429 is to enter into engagement with aseasso a low dwell portion m of the cam run. As the follower 440 engages the low dwell portion 404,

'with bolt 420 attached to clamping lever 420.

when extension 44! engages bolt 420, lever 420 is rotated in a clockwise direction about its pivot, and engages pointer, 402 clamping it against the bar 420. .At the same time, pin 400 moves counter-clockwise .and causes bell-crank lever 432 to be turned counter-clockwise on the pivot 434.=

During this counter-clockwise movement of bellcrank lever 402, spring 421. causes supporting arm 402 and secondary pointer 40! to follow until the arms 440 and 44! of pointer 42! engage the. galvanometer pointer 402, and the-stop 443, respectively. It will of course be understood that the engagement of arm 440' with galvanometer pointer 402 will not take place exactly simultaneously with the engagement of arm 44! and'stop 443, but that one of these engagements will take place before the other, depending upon the position of pointer 402 and the previous position of secondary pointer 42! with respect to varm 402. After one of these engagements take place, further counter-clockwise movement of supporting arm 432 causes secondary pointer 42! tolrotate about the slip friction pivot 42i until the other engagement takes place. After arm 440 has engaged pointer 402, and arm 44! has en aged stop 442, further counter-clockwise rotation of bellcrank lever 432 will merely cause separation of surfaces 435 and 42,0 and tensioning'of strain release spring 431. It will be seen that this operation establishes the secondary pointer 42! in an angular position with respect to the supp'porting arm 402 which is determined by the position of galvanometer pointer 402;

As clockwise rotation of cam 400 continues, follower 440 passes over the low dwell portion 404 and engages the riser portion 455. This causes rotation of driving arm 422 in a clockwise direction against the tension of spring 45!. At approximately the same time, the pin 4" moves out of engagement with the lower end of hellcrank lever 432, permitting the latter to rotate clockwise under the influence of spring 452. Since lever 420,- thereby releasing galvanometer pointer 402; The partsare so proportioned that when pin 444 engages the surface of slide-wire 401, the

' pivot 42! on supporting arm 402 will belexactly in line with shaft 440 of slide-wire 401. The surfaces of pin 400 and slide-wire 401 are frictional in character. so that the engagement between them is quite positive. This engagement is made more positive by the tensioning of spring 402 as driving arm 422 continues to rotate clockwise after the motion of bell-crank lever 400 has been stopped by engagement of pin 444 with slidewire'401. Clookwise notion of driving arm 422- 440 or 44! of secondary pointer 42!. The particular pin to engage pointer 42! is determined by the angular position of secondary pointer 42! with respect tosupporting arm 422. If galvanometer pointer arm 402 was clamped in the center of its range of travel, secondary pointer arm 42! will be at a central position with respect to supporting arm 422, and the arms 440 and 44! will both be barely engaged by the pins 446 and 441 when the driving arm 422 is at the extremity of its range of movement to the right. If the galvanometer pointer 402 is clamped at a point to the left of the position shown' in the drawings, the secondary pointer 42! will be displaced in a counter-clockwise direction from its central position with respect to supporting arm 422. In this condition, the pin 440 will engage arm 440 when the driving arm moves to the right, and will rotate secondary pointer 42! back to its normal position. Since at this time; the pm 444 is frictionally engaging the surface of slide-wire 401, the slide-wire 401 will likewise be rotated in a clockwise direction by an amount corresponding to the deflection of galvanometer pointer 402-from its central position. Y If, on the other hand, the pointer 402 is deflected to the right from the position shown in the drawings, the position assumed by the secondary pointer 42! will be displaced in a clockwise direction from its central position withrespect to supporting arm 402, and the arm 44! will be engaged by pin 441 as the driving-arm 422 moves to the right. Pin 441 will drive secondary pointer 42! back to its normal position withxespect to supporting am 422, and through the frictional connection between pin 444 and slide-wire 401, the latter will be rotated counter-clockwise by an the clockwise rotation of bell-crank lever 400 amount corresponding to' the deflection of galvanomete'r pointer 402 from its center position.

when the network 400 is balanced, the E. M. F. supplied by the thermocouple 400 is substantially equal to the potential drop across that portion of slide-wire 401 between slider M0 and the conductor 2. Under these conditions, no current flows through galvanometer coil 404, and pointer 402 is therefore at its center position. Upon a change in temperature adjacent the thermocouple 400, the changed thermocouple E. M; F. unbalances the network, and a flow of current takes place through galvanometer coil 404, causing a deflection of inter 402. The sensitive relay mechanism 40! then rotates slide-wire 401 by anamount and in a direction proportional to the deflection of pointer 402, thereby changing the cause counter-clockwise movement of clamping 40! to a condition of balance.

Rotation of slide-wire 401 also rotates shaft 400, which may be connected by suitable electrical or mechanical means to any desired indicating,

recording. or controlling apparatus. For example. the shaft 400 could operate a potentiometer in a control network such as the potentiometer 340 in network 240 of Figure 3.

While I have shown and described certain preferred embodiments of my invention, other modiflcations thereof will readily occur to those skilled in the art, and'I therefore wish it to be understood that my invention is limited only by the appended claims.

I claim as my invention:

1. In a sensitive relay mechanism, in combi-- nation, a member for performing a control functlon. an operator for engaging said member so as continues until either pin 440 or 441 engages arm 70 to cause it to perform said control function, a

movable support for said operator, means for sitioning said operator with rebpect to saidsupport in accordance with a controlling condition, brake means for preventing movement of said operator with respect to said support, and motor means for reciprocating said brake means into and out of engagement with said operator, said motor means being effective upon continued movement thereof after engagement of said brake means with said operator to transmit motion to said supp rt through said brake means and said operator, so that said operator is moved into engagement withsald control member.

2. In a sensitive relay mechanism, in combination, a member for performing a control function, an operator for engagingesaid member so as to cause it to perform said control function, a movable support for said operator, means for positioning said operator with respect to said support in accordance with a controlling condition, brake means for preventing movement of said operator with respect to said support, said brake means comprising a first brake member adapted to engage a first portion of said operator and a second brake member adapted to engage a second portion of said operator, said first and secnd portions being in opposed relation so that said operator is clamped between said brake members when both are engaging the operator, and motor means for operating said brake means and reciprocating said support so as to sequentially release said brake means, engage said operator with said positioning means, app y said brake means, and engage said operator with said control member.

3. In a sensitive relay mechanism, in combination, a galvanomc ll pointer, means for deflecting said pointer in accordance with the value of a controlling condition, means for clamping said pointer, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function, a support for said operator, brake means for preventing movement of said operator with respect to said support, said brake means comprising a first brake member adapted to engage a first portion of said operator and a second brake member adapted to engage a second portion of said operatcr, said first and second portions being in opposed relation so that said operator is clamped between said brake members when both-are engaging the operator, one of said brake members having an extension for engaging said clamping means, engagement of said extension and said clamping means serving to release said brakefor operating said brake means, and reciprocating said support so as to sequentially clamp said 2,ses,aso 4 being effective to drive said brake means after its engagement with said operator so as to transmit motion to said support through said brake means and said operator, thereby causing engagement of said operator with said control member, said motor means comprising a cam and a follower therefor associated with said brake means, said cam being shaped to control the rate of change of position of said follower so that the period of engagement of said operator with said control member is a function of the position of the operator with respect to the support.

5. Ina sensitive relay mechanism, in'combination, a member for performing a control function,

an operator for engaging said member so as to cause it to perform said control function, a movable support for said operator, means for positioning said operator with respect to said support in accordance with a controlling condition, brake means for preventing movement of said operator with respect to said support, means biasing said support so as to engage said operator with said positioning means, and. motor means for reciprocating said brake means into and out of engagement with said operator, said motor means being efl'eotive to drive said brake means after its engagement with said operator so as to transmit motion to said support through said brake member and clamp said pointer, and motor means I means and said 0 rator, thereby causing engagement of said operator with said control member, said motor means comprising a cam and a foilower therefor associated with said brake means, said control member having a portion of its con tour oblique with respect .to the path of movement of the operator, so that the period of engagement of said operator with said control membar is a function of the position of the operator with respect to its support.

6. In a sensitive relay mechanism, in combination, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function, a movable support for said operator, means for positioning said operator with respect to said support in accordance with a controlling condition, means for reciprocating said support so as, to cause engagement of said operator with said control member, said control member having a portion of its contour oblique with respect to the path of movement of the operator, so that the period of engagement of said operator with said control member is a function of the position of the operator with respect to its support.

'7. In a sensitive relay mechanism, in combination, a galvanometer pointer, means for deflecting said pointer in accordance with the value of a controlling condition, means for clamping said pointer, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function, a secondary pointer, and motor means for driving said clamping means, said secondary pointer, and

tion, a member for performing a control func-.

tion, an operator for engaging said member so as to cause it to performsaid control function, a

movable support for said operator, means for po-j sitioning said operator with respect to said sup- Port in accordance with a controlling condition,

brake means for preventing movement of said operator with respect to said support, means biasing said support'so as to engage said operator with said positioning means, and motor means for reciprocating said brake means into and out of; engagement with said operatonsaid motor means said operator so as to sequentially clamp said galvanometer pointer, position said secondary pointer in accordance with the position of said clamped pointer, position said operator in accordance with the position of said secondary pointer, unclamp said galvanometer pointer and drive said operator into engagement with said control member. s 8. In a sensitive relay mechanism, in combination, a memberfor performing a control function, an operator forlengaging said member so as to cause it to perform said control function, a movable support for said operator. means for posiaseasso tioning said operator with respect to said support in accordance with a controlling condition, brake means for preventing movement of said operator with respect to said support, a strain release connection between said brake means and said support, said positioning means serving as a stop for said operator andv said support. said brake means being released from said operator when said operator engages said positioning means, and motor means including said brake means for driving said operator into engagement with said control member.

9. In a sensitive relay mechanism, in-combination, a galvanometer pointer, means for deflecting said pointer in accordance with the value of a controlling condition, means for clamping said pointer, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function, a movable support for said operator, brake means for preventing movement of said-operator with respect tosaid support, means attached to said brake means for engagingsaid clamping means so as to clamp said pointer and simultaneously release said brake means, and motor means for operating said brake means and reciprocating said support so as to sequentially clamp said pointer, release said brake means, engage said operator with said clamped, pointer, apply said brake means, unclampsaid pointer, and engage said operator with said control member.

10. In a sensitive relay mechanism, in combination, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function, a movable support for said operator, means for positioning said operator with respect to said support in accordance with a controlling condition, brake means for preventing movement of said operator with respect to said support, and

. motor means for reciprocating said brake means so as to drive the brake means into engagement with the'operator and thereafter move the brake means, operator and support as a unit, said motor means comprising a single cam and a follower therefor attached to said brake means, said motor means and saidbrake means cooperating upon continuous movement of said cam to sequentially release said brake means from said operator, engage said operator with said positioning means, apply said brake means, and engage said operator with said control member.

. .11. In a sensitive relay mechanism, in combination, a member for performing a control function,.an operator for engaging said member so as to cause it to perform said control function, a movable support for said operator, means for positioning said operator with respect to said support in accordance with a controlling condition, brake means for preventing movement of said operator with respect to said support, and motor as to cause it to perform said control function, a movable support for said operator, means for positioning said operator with respect to said support in accordance with a controlling condition, brake means for preventing movement of said operator with respect to said support, said brakemeans comprising a first brake member adapted to engage a first portion of said operator and a second brake member adapted to engage a second portion of said operator, said first and second portions being in opposed relation so that said operator is'clamped between said brake members when both are engaging the operator,

and motor means for reciprocating said brake means so as to drive the brake means into engagement with the operator and thereafter move the brake means, operator and support as a unit, said motor means comprising a single cam and afollower therefor attached to one of said brake members, said motor means and said brake means cooperating upon continuous movement of said cam to sequentially release said brake means from said operator, engage said operator with said positioning means, apply said brake means, and engage said operator with said control member.

13. In a sensitive relay mechanism, in combitioning said operator with respect to said support meansfor reciprocating said brake means so as to drive the 'brake means into engagement with of the operator with respect to the support. a

12. In a sensitive relay mechanism, in combination, a member for performing a control function, an operator for engaging said member so in accordance with a controlling condition, brake means for preventing movement of said operator with respect to said support, said brake means comprising a first brake member adapted to engage a first portion of said operator and a second brake member adapted to engage a second portion of said operator, said first and second por. tions being-in opposed relation so that said operator is clamped between said brake members when both are engaging the operator, means biasing said second brake member into engagement with said operator, stop-means for limiting movement or said second brake member, and motor means for reciprocating said first brake member so as to drive,the first brake member into engagement with the operator and thereafter move the first brake member, operator, and support as a unit, said unit moving thereafter so that said operator engages said second brake member and moves the second brake member with said unit, said motor means and said brake means cooperating to sequentially release said brake means from said operator, engage said operator with said positioning means, apply-said brake means, and engage said operator with said control member.

14. In a sensitive relay mechanism, in combination, a galvanometer pointer, means for deflecting said pointer in accordance with the value of a controlling condition, means for clamping said pointer, a member for performing a control function, an operator for engaging said memher so as to cause it to perform said control function, means for positioning said operator in accordance with the position of the clamped pointer, and means for reciprocating said operator betweenithe positioning means and the con- B sing a portion of said operator spaced from said pointer.

15. In a sensitive relay mechanism, in combi-- nation, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function, means for reciprocating said operator along an arcuate path, means for varying the radius of said path in accordance with a controlling condition, said control member having a portion of its contour oblique with respect to the paths of movement of the operator, so that the period of engagement of the operator with the control member is a function of the radius of said path.

16. In a sensitive relay mechanism, in combination, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function,

said control member, said reciprocating means 7,

o,ses,eso

including a driving arm and strain release spring means connecting said support and said arm so as to cause said support to move in unison with said arm, but to permit separation of said support from said arm when movementof said supso as to cause it to perform said control function, a a movable support for said operator, pointer means for reciprocating said operator along one of a plurality of concentric arcuate paths so as to cause engagement of said operator and said means variable in position in accordance with a controlling condition, means for reciprocating said support between said pointer means and said control member so as alternately to position said operator with respect to said support in accordance with the position of said pointer means and then tomove said operator to engage said control member, said reciprocating means including a control member, and meansior shifting said operator from one to another of said paths in accordance with a controlling condition, said control member having a portion of its contour oblique, with respect to said paths of movement,

so that the period of engagement of the operator with the control member is determined by the particular path in which the operator is reciprocated.

17. In a sensitive relay mechanism, in combination, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function,

strain release means supporting said control 1 member so as to permit movement of the con trol member when engaged by the operator, means for reciprocating said operator along one of a plurality of concentric arcuate paths so as to cause engagement of said operator and said control member, and means for shifting said operator from one to another of said paths in ac-- cordance with a controlling condition, saidcontrol member having a portion or its contour oblique with respect to said paths of movement,

so that the period of engagement of the operator with the control member is determined by the particular path in which the operator is reciprocated.

1.8. In a sensitive relay mechanism, in combination, a plurality of members for performing different control functions, an operator for selectively engaging one of said members so as to cause it to perform its control function, strain i bination, a member for performing a control function, an operator for engaging said member so as to cause it to perform said control function,

a movable support for said operator, pointer means variable in position in accordance with a controlling condition, and means for reciprocating said support between said pointer means and said control member so as alternately to position said operator with respect to said support in accordance with the position of said pointer means and then-to move said operator to en age driving arm and strain release spring means connecting said support and said arm so as to cause said support to move in unison with said arm, but to permit separation of said support from said arm when movement of said support is limited by engagement of said operator and said pointer means, 'cam means for operating said driving arm in one direction, and spring means for operating said driving arm in the opposite direction.

21. In a sensitive relay mechanism, in combination, a movable member for performing a control function and for varying the resistance in an electrical circuit, an operator for engag .ing said member so'as to cause it to perform said control function and vary said resistance, a movable support for said operator, pointer means variable in position in accordance with a controlling condition, and means for reciprocating said support between said pointer means and said control member so as alternately to position said operator with respect to said support in accordance with the position oi said pointer means and then to move said operator to engage-said control member, said reciprocating means including adrivin'g arm and strain release spring means connecting said support and said arm so as to causesaid support to move in unison with said arm, butto permit separation of said support from said arm when movement of said support is limited by engagement of said operator and said pointer means.

22. In a sensitive relay mechanismjor operating a control device in accordance with the position of a galvanometer pointer, in combination, means for periodically clamping said" pointer, in. secondary pointer having a portion adapted to mechanically engage said control device, a support for saidsecondary pointer, means for reciprocating said support between said galvanometer pointer and said control device so as alternately to position said secondary pointer with respect to said support in accordance with the position of said galvanometer pointer and then to move said portion of said secondary pointer into engagement with said control device, and

driving means operative while said portion engages said control device to change the position of said secondary pointer with respect to said support, and thereby operate said control device through said mechanical engagement.

THODMS R. HARRISON. 

